Design and Analysis of Metal Oxides for CO<sub>2</sub> Reduction Using Machine Learning, Transfer Learning, and Bayesian Optimization

Iwama, Ryo; Takizawa, Kenji; Shinmei, Kenichi; Baba, Eisuke; Yagihashi, Noritoshi; Kaneko, Hiromasa

doi:10.1021/acsomega.2c00461

Cited by 17 publications

(15 citation statements)

References 37 publications

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“…Experimental data and descriptors of metal oxides, such as Pymatgen 22 and Materials project descriptors, 23 were obtained from a previous report, 15 and regression models were constructed to predict CO 2 and H 2 conversion rates as previously reported. 15 In the case of the CO 2 conversion rate, x represented the experimental conditions and Pymatgen and materials project descriptors. For the H 2 conversion rate, represented the experimental conditions and Pymatgen descriptors.…”

Section: Resultsmentioning

confidence: 99%

“…Manufacturing the desired product via the RWGS-CL reaction process requires metal oxide and process designs and testing in pilot and actual plants. In recent years, both metal oxide 15 and process designs 16 have been conducted using machine learning. A statistical model y = f ( x ) is constructed using a dataset between x and y , which represent the synthesis conditions and the properties and activities, respectively, and the dataset is an experimental dataset in metal oxide design.…”

Section: Introductionmentioning

confidence: 99%

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Integration of Materials and Process Informatics: Metal Oxide and Process Design for CO₂ Reduction

Iwama

Kaneko

2022

ACS Omega

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In materials informatics, a mathematical model constructed between the synthesis conditions of materials and their properties and activities is used to design synthesis conditions in which the properties and activities have the desired values. In process informatics, a mathematical model constructed between the process conditions for devices and industrial plants and product quality and cost is used to design process conditions that can produce the desired products. In this study, we propose a method to simultaneously design the synthesis conditions of materials and the process conditions of products by integrating materials and process informatics in the reverse water-gas shift chemical looping (RWGS-CL) reaction, which produces CO from CO2 using metal oxides via the RWGS-CL process. Four methods: Gaussian process regression-Bayesian optimization (GPR-BO), Gaussian mixture regression–Bayesian optimization (GMR-BO), GMR-BO-multiple, and GPR-GMR-BO were investigated for the optimization. All four proposed methods outperformed the results of a random search. GPR-BO achieved the highest performance and proposed 27 promising candidates for the synthesis conditions and metal oxides. The selected metals did not include Cu and Ga, which tended to have high predicted CO2 and H2 conversion rates, but Fe and La, which had slightly lower predicted CO2 and H2 conversion rates. These results indicate that a combination of metal oxides with lower predicted CO2 and H2 conversion rates and optimized process conditions was important for the optimization of both materials and processes, which was achieved by integrating materials and process informatics via the proposed method. Thus, we confirmed that it is possible to simultaneously optimize the combination of metals, composition ratios, synthesis conditions of the material or the metal oxide, and the process conditions using experimental datasets, process simulations, and machine learning, such as GPR, GMR, BO, and multiobjective optimization with a genetic algorithm.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Integration of Materials and Process Informatics: Metal Oxide and Process Design for CO₂ Reduction

Iwama

Kaneko

2022

ACS Omega

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“…This method has been employed to improve the accuracy of the prediction of optimized experimental conditions for metal oxides to achieve target CO 2 and H 2 conversion extents using the knowledge of oxygen vacancy formation energy from a pretrained model. 42 However, the problems encountered by these methods are quite different from the typical supervised learning methods. The utilization of these methods requires a strong correlation between the knowledge of the pretrained source model and the target task domain.…”

Section: Various ML Methodologies Used For Co 2 Rrmentioning

confidence: 99%

“…Later, this active learning method was adopted by others to predict the important descriptors of CO 2 RR for different Cu-based alloy systems. , Transfer learning is another interesting method which utilizes the knowledge from a pretrained model and reuse as a foundation point for another task, reducing the computational cost of producing labeled data. This method has been employed to improve the accuracy of the prediction of optimized experimental conditions for metal oxides to achieve target CO 2 and H 2 conversion extents using the knowledge of oxygen vacancy formation energy from a pretrained model . However, the problems encountered by these methods are quite different from the typical supervised learning methods.…”

Section: Various ML Methodologies Used For Co2rrmentioning

confidence: 99%

A Route Map of Machine Learning Approaches in Heterogeneous CO₂ Reduction Reaction

et al. 2023

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Machine learning (ML) with its indigenous predicting ability has been influential in the current scientific world and has enabled a paradigm shift in the field of CO2 reduction reaction (CO2RR). In this perspective, current research progress of ML approaches in heterogeneous electrocatalytic CO2RR has been demonstrated. The important findings related to the ML systems comprising features, output descriptors, and ML models have been summarized. Further, the opportunities and challenges in using the state-of-the-art ML methodologies along with the ways of circumventing those challenges are discussed. Finally, the interpretation of black box ML models and extensive usages of interpretable glass box and gray box models for CO2RR are encouraged for obtaining proper physical interpretations. The future directions on utilizing several such evolving ML methods to predict catalytic activity descriptors can help in a broader way to explore novel and efficient heterogeneous CO2RR and other similar catalytic reactions.

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“…The multiobjective optimization for maximizing methanol production and reducing carbon emission uses the genetic algorithm . Using machine learning and Bayesian optimization, they created metal oxides while jointly optimizing experimental parameters to meet the target CO 2 and H 2 conversion predictions . However, to the best of the authors’ knowledge, hardly any work has been reported in the literature that employs interpretable GPR models in a multiobjective Bayesian optimization framework, specifically for syngas-to-methanol conversion.…”

Section: Introductionmentioning

confidence: 99%

Multiobjective Bayesian Optimization Framework for the Synthesis of Methanol from Syngas Using Interpretable Gaussian Process Models

et al. 2022

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Methanol production has gained considerable interest on the laboratory and industrial scale as it is a renewable fuel and an excellent hydrogen energy storehouse. The formation of synthesis gas (CO/H 2 ) and the conversion of synthesis gas to methanol are the two basic catalytic processes used in methanol production. Machine learning (ML) approaches have recently emerged as powerful tools in reaction informatics. Inspired by these, we employ Gaussian process regression (GPR) to the model conversion of carbon monoxide (CO) and selectivity of the methanol product using data sets obtained from experimental investigations to capture uncertainty in prediction values. The results indicate that the proposed GPR model can accurately predict CO conversion and methanol selectivity as compared to other ML models. Further, the factors that influence the predictions are identified from the best GPR model employing "Shapley Additive exPlanations" (SHAP). After interpretation, the essential input features are found to be the inlet mole fraction of CO (Y(CO, in)) and the net inlet flow rate (Fin(nL/min)) for our best prediction GPR models, irrespective of our data sets. These interpretable models are employed for Bayesian optimization in a weighted multiobjective framework to obtain the optimal operating points, namely, maximization of both selectivity and conversion.

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Design and Analysis of Metal Oxides for CO₂ Reduction Using Machine Learning, Transfer Learning, and Bayesian Optimization

Cited by 17 publications

References 37 publications

Integration of Materials and Process Informatics: Metal Oxide and Process Design for CO₂ Reduction

Integration of Materials and Process Informatics: Metal Oxide and Process Design for CO₂ Reduction

A Route Map of Machine Learning Approaches in Heterogeneous CO₂ Reduction Reaction

Multiobjective Bayesian Optimization Framework for the Synthesis of Methanol from Syngas Using Interpretable Gaussian Process Models

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Design and Analysis of Metal Oxides for CO2 Reduction Using Machine Learning, Transfer Learning, and Bayesian Optimization

Cited by 17 publications

References 37 publications

Integration of Materials and Process Informatics: Metal Oxide and Process Design for CO2 Reduction

Integration of Materials and Process Informatics: Metal Oxide and Process Design for CO2 Reduction

A Route Map of Machine Learning Approaches in Heterogeneous CO2 Reduction Reaction

Multiobjective Bayesian Optimization Framework for the Synthesis of Methanol from Syngas Using Interpretable Gaussian Process Models

Contact Info

Product

Resources

About

Design and Analysis of Metal Oxides for CO₂ Reduction Using Machine Learning, Transfer Learning, and Bayesian Optimization

Integration of Materials and Process Informatics: Metal Oxide and Process Design for CO₂ Reduction

Integration of Materials and Process Informatics: Metal Oxide and Process Design for CO₂ Reduction

A Route Map of Machine Learning Approaches in Heterogeneous CO₂ Reduction Reaction